Nonvolatile rotation sensor with magnetic particle in serpentine track

What we claim is: 1. A rotation sensor comprising: a housing adapted to receive a shaft within the housing to rotate about an axis; a magnetic particle; a track constraining the magnetic particle for movement therealong and positioned about the axis, the track providing a periodic variation in radius with respect to the axis so that the magnetic particle moving through the track about the axis moves closer to and further from the axis with such movement; a permanent magnet positioned adjacent to the track; wherein: one of the track and the permanent magnet are attached to the shaft so that the track and the permanent magnet rotate relative to each other about the axis; rotation of the track and the permanent magnet relative to each other thereby presents to the magnetic particle a magnetic field having a component oscillating radially with respect to the axis; and the component of the magnetic field oscillating radially with respect to the axis causes the magnetic particle to advance a predetermined amount along the track with each rotation of the shaft; and a sensor system identifying a location of the magnetic particle along the track to output a number of turns of the shaft according to the location of the magnetic particle along the track. 2. The rotation sensor of claim 1 wherein the permanent magnet is a magnetic ring mounted eccentrically with respect to the track so that a portion of the magnetic ring passes from a radially outboard position to a radially inward position with respect to a given location on the track as the shaft rotates. 3. The rotation sensor of claim 1 wherein the permanent magnet provides periodically extending radial teeth exerting a tangential force on the magnetic particle in the track when the teeth pass the magnetic particle with rotation of the shaft. 4. The rotation sensor of claim 1 wherein the magnetic particle is selected from the group consisting of a ferromagnetic bead, a droplet of ferrofluid, and a droplet of ferrofluid surrounding a magnetized bead. 5. The rotation sensor of claim 1 wherein the track is a substantially sinusoidal path along a circle lying in a plane perpendicular to the axis. 6. The rotation sensor of claim 1 wherein the sensor system uses sensors selected from the group consisting of optical, resistive, capacitive, and inductive sensors. 7. The rotation sensor of claim 5 wherein the sensor system uses noncontact electrical field sensors. 8. The rotation sensor of claim 1 further including a second magnetic particle and a second track constraining the second magnetic particle and concentric with the first track, the second track providing a serpentine periodic variation in radius from the axis so that the second magnetic particle moving to the second track about the axis moves closer to and further from the axis with such movement; wherein the sensor system identifies a location of the second magnetic particle along the second track to reveal a number of turns of the shaft according to a position of the second magnetic particle along the second track. 9. The rotation sensor of claim 8 wherein the second magnetic particle is angularly displaced from the magnetic particle. 10. The rotation sensor of claim 8 wherein the number of serpentine periodic variations in the first and second tracks are different to increase a number of turns of the rotation sensor shaft providing a unique output according to a least common multiple of the different numbers of serpentine periodic variations. 11. The rotation sensor of claim 1 wherein the sensor system provides an electrical output connector providing a signal indicating a number of rotations of the shaft. 12. The rotation sensor of claim 1 wherein the sensor system provides electrical output providing a signal differentiating at least two angular positions of the shaft within a range of 360 degrees. 13. The rotation sensor of claim 1 wherein the sensor system provides a continuous output value indicating the location of the magnetic particle along the radial guide. 14. The rotation sensor of claim 12 further including an absolute rotation sensor attachable to the shaft for providing an indication of a plurality of angular positions within a range of 360 degrees of shaft rotation. 15. The rotation sensor of claim 1 wherein the permanent magnet is mounted to rotate with the shaft. 16. The rotation sensor of claim 1 wherein the sensor system provides periodic sensor elements at locations associated with each periodic variation in the radius of the track to identify a location of the magnetic particle at any of such location. 17. The rotation sensor of claim 1 wherein the sensor system provides continuous measurement of the location of the magnetic particle along the track. 18. The rotation sensor of claim 1 wherein the track is a channel constraining the magnetic particle to move along the channel. 19. The rotation sensor of claim 1 wherein when the shaft is fixed in position, the magnetic particle is stably held in a single location along the track by a magnetic field. 20. A method of measuring absolute rotational turns employing a rotation sensor having: a housing adapted to receive a shaft within the housing to rotate about an axis; a magnetic particle; a track constraining the magnetic particle from movement therealong and positioned about the axis, the track providing a periodic variation in radius with respect to the axis so that the magnetic particle moving through the track about the axis moves closer to and further from the axis with such movement; a permanent magnet; wherein one of the track and the permanent magnet are attached to the shaft to rotate relative to each other about the axis thereby presenting to the magnetic particle a magnetic field oscillating radially with respect to the axis causing the magnetic particle to advance a predetermined amount along the track with each rotation of the shaft; and a sensor system identifying a location of the magnetic particle along the track; the method comprising: (a) rotating the shaft to generate rotation of the track and the permanent magnet relative to each other; (b) causing the magnetic particle to move along the track as a function of the magnetic field oscillating radially with respect to the axis; and (c) sensing the location of the magnetic particle to reveal a number of turns of the shaft according to a position of the magnetic particle along the track.